Journal of Physics Conference Series
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The investigation of movement dynamics of an ACelectric arc attachment along the working surfaceof a hollow cylindrical electrode under the action ofgas-dynamic and electromagnetic forcesTo cite this article A V Surov et al 2012 J Phys Conf Ser 406 012007
View the article online for updates and enhancements
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The investigation of movement dynamics of an AC electric arc
attachment along the working surface of a hollow cylindrical
electrode under the action of gas-dynamic and
electromagnetic forces
A V Surov
1 2 S D
Popov
1 2 ЕО Serba
1 G V Nakonechny
1 V А
Spodobin
1
R V Ovchinnikov1 I I Kumkova
1 S A Shabalin
1
1 Institute for Electrophysics and Electric Power of Russian Academy of Sciences
18 Dvortsovaya emb 191186 StPetersburg Russia 2 StPetersburg State Polytechnical University 29 Polytechnicheskaya 195251
StPetersburg Russia
E-mail alex_surovmailru
Abstract Stationary electric arc alternating current plasma torches are used today for
realization of plasma chemical technologies requiring relatively high energy input Waste
treatment is one these directions The paper reports on experiment results directed towards the
increase in the lifetime characteristics of electrode units of the powerful high-voltage electric-
arc AC plasma torches The solution to the problem of obtainment the uniform wear of a
copper hollow cylindrical electrode achieved by the controlled movement of the arc attachment
along the working surface was offered Organization of gas supply in the near electrode area
and application of alternating magnetic field ensured movement of arc attachment along the
surface with average speed from 2 to 14 ms Arc current was about 47 A and 84 A gas flow
rate in near electrode area was about 5 and 45 gs Due to researches on the experimental
prototype of a hollow cylindrical electrode the erosion of its material reached only 3 microgC that
enables production of the electrode assembly with life time above 1000 hours at currents in the
arc up to 100-200 A
Introduction
Currently plasmachemical technologies are actively developed for efficient use of energy resources
and implementation of ecologically safe methods for destruction and treatment of various wastes
including for the combustible syngas production [1-5] The generator of thermal plasma is a key
element of the majority of plasma chemical installations Nowadays plasma torches are also actively used in power engineering for ignition and lightning of coal boilers [6] The devices intended for
operation in large-scale industrial installations should be powerful efficiently transfer energy to the
working gas operate continuously for a long period of time and generally can operate in oxidizing media Stationary electric arc plasma torches are very promising for these purposes Westinghouse [7]
and Europlasma [8] DC plasma torches are well-developed for industrial applications The particular
attention for a number of applications deserves the models using water or steam as a plasma forming gas [5 9 10] A number of promising models of stationary AC plasma torches operating on various
gases has been developed in IEE RAS Among them are plasma torches using oxidizing media
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
Published under licence by IOP Publishing Ltd 1
(including air) powerful single-chamber three-phase plasma torches with rod electrodes [11] single-
phase and three-phase high-voltage plasma torches with power from 5 up to 100 kW with rod electrodes mounted in a separate cylindrical channels [12 13] and single-chamber three-phase plasma
torches with rail-type electrodes with operating power up to 500 kW [14] and plasma torches
working on a mixture of steam and air or another gas with power up to 100 kW were developed [15]
At present high-voltage AC plasma torches with hollow cylindrical electrodes are under development
Such plasma torches have the high arc voltage drop that enables essential current decreasing versus
low-voltage models of the same power level and accordingly increase of the electrode lifetime As a
result these devices can provide continuous operation with high power and lifetime of electrodes more
than 1000 hours Prototypes of commercial plasma torches with power 200 and 400 kW are created
The devices with power of an order 1 MW are under development This paper is devoted to
investigation of movement dynamics of an AC electric arc attachment along the working surface of a
hollow cylindrical electrode of such plasma torches The purpose of this paper is presentation of
results of the experimental researches obtained during development of new AC plasma torches
Experimental setup
The investigations were carried out at the test bench of AC plasma torches equipped with required
supply systems The test bench comprises power supply system double-loop cooling system system
of preparation and supply of plasma forming gas and system of treatment and discharge of exhaust
gases Prototypes of AC plasma torches with cylindrical (hollow) electrodes developed by IEE RAS
were used Figure 1 shows the schematic diagram of the installation The high-voltage three-phase
plasma torch is connected to the AC power supply source of industrial frequency (50 Hz) While the
plasma torch operates the arcs burn between three electrodes and have the general point behind the
nozzle exit section
Figure 1 Schematic diagram of the
experimental installation 1 - Power supply
2 - high-voltage three-phase plasma torch
with cylindrical (hollow) electrodes 3 - arc
column 4 - hollow cylindrical electrode 5 -
solenoid 6 - pipe hole for photo and video
shooting 7 - terminal for connection of the
power supply 8 and 9 - upstream and
downstream loops of tangential supply of plasma forming gas 10 - high-speed video
camera 11 - recording industrial computer
In the bottom of Figure 1 (zoomed in) is shown the schematic diagram of one of three plasma torch
channels (one of three phases) with electrode solenoid and peep hole From both sides of a hollow
electrode (upstream and downstream) are designed loops of tangential plasma forming gas supply
Rotation of the arc attachment in each of the electrodes is provided due to the tangential gas supply
and the magnetic field of the solenoid installed coaxially around the electrode The current and voltage
analogue sensing transducers are incorporated for measurement of arc currents and voltages in the
power supply The industrial computer with an acquisition boards (with bandwidth of 10 kHz per
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
2
channel) is incorporated in the measuring system for data recording Power of the plasma torch and
effective values of electric parameters are calculated on their instantaneous values There are
automated pressure regulators - the flow meters which are also connected to the industrial computer
for supply of the required plasma forming gas flow rate into the plasma torch gas inlet loops The peep
holes are provided for measurement of speed of the arc attachments on the electrode surface by means
of a high-speed video shooting Three monochrome high-speed video cameras which are a part of the
measuring system allow simultaneous synchronous recording of arc attachment movement along the
three electrodes with speed of shooting 4000 fps
Description of experiments and main results
Experiments were carried out on prototypes of the plasma torch working models Considering the
practical importance of the carried-out investigations the principal criterion for the flow rate range
selection for a gas supply mode variation and solenoid parameters for the magnetic field change were
expediency and feasibility of providing these parameters during the plasma torch work in the industrial
plants Investigations were carried out on modes of the stable arc burning in the plasma torch electrode
channels for the arc currents about 40A and 80A Longitudinal and rotary moving of the arc
attachment ndash in the axial and tangential directions was required for providing the long-lasting lifetime
of electrodes Figure 2 shows the photo of the arc attachment The photo made through the peep hole
under some angle to the axis of the plasma torch channel in order to see the electrode working surface
Figure 2 Photo of an AC electric arc attachment
on the working surface of the cylindrical electrode
shutter speed 14000 s
The internal part of the cylindrical electrode surface where during the plasma torch work the arc
attachment leaves the trace we will call a working surface The arc attachment position on the
electrode working surface in the longitudinal direction was possible to set by regulation of the flow
rates in near-electrode loops of the plasma forming gas supply The rotation speed of the arc
attachment depends both on the gas supply mode and on characteristics of the impressed magnetic
field
The AC arc attachment rotates under the action of the gas-dynamic forces sliding over the
electrode working surface during the plasma torch work Plasma of the arc column does not have
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
3
enough time to relax at the current zero crossing and the arc is ignited in the same channel in the each
following half-period The solenoid which is forming a longitudinal magnetic field in the hollow
electrode volume is coaxially put on the electrode for the intensification of the arc attachment
rotation The solenoid coil is powered from the AC power supply so that at the arc current polarity
changing the current direction in the coil changes Thus despite of the arc current polarity changing
the force direction acting on the arc attachment and promoting the intensification of its rotational
movement remains the same The magnitude of force acting on the charged particles of the arc column
in the arc attachment area changes due to the sinusoidal change of the current in the coil This force
reaches the maximum value at the peak arc current and decreases at the moment of the current
transition through zero The connection of the AC coil in the opposite direction can cause the braking
or even arc attachment moving towards to the gas flow which is undesirable as it leads to increase of
the electrode material erosion and the reduction of its lifetime
The magnetic field produced by a solenoid in the electrode channel was obtained using computer
simulation Figure 4 shows the schematic diagram of the electrode with the solenoid (a) and
characteristic graphs of distribution of value of magnetic inductance on a working surface of an
electrode in the longitudinal direction (b) and its distributions along the diameter of the electrode
chamber (c) Values of magnetic inductance during the moments of time matching to maxima of
currents in the solenoid windings for the points of space laying on lines L and D are built in the
graphs Line L represents the generating line of the working surface and line D coincides with the
diameter
A
L
D
A
L
D
(a)
00 02 04 06 08 lL
4
8
12
16
20
B10-3
T (b)
00 02 04 06 08 dD
4
8
12
16
20
B10-3T
1
2
3
4
5
(c)
Figure 3 Schematic diagram of the hollow cylindrical electrode with solenoid (a) and characteristic
graphs of distribution of the value of the magnetic inductance in the electrode channel at the moment
of current maximum in the solenoid windings Lines D and L ndash lines along which are calculated the
values of magnetic inductance presented in graphs (b) - longitudinal distribution of the magnetic
inductance along the electrode working surface (c) - distribution of the magnetic inductance on the
diameter of the electrode chamber Point A belongs to ring area with the maximum magnetic field
density on the electrode working surface Curve 1 shows magnetic inductance for plasma torch
working with arc current of 47 A curves 2-5 correspond the plasma torch working modes with arc
current of 85 A
Analysis of materials of a high-speed video shooting of the arc attachment movement along the
electrode surface shows dependences of the arc attachment versus plasma torch operating parameters
and characteristics of applied magnetic field Shooting was carried out through the peep holes located
in a back part of the electrode channel with use of High Speed Video Cameras ldquoCitius Imaging C100
Centuriordquo with a speed 4000 fps and exposure 2 micros Speed of the arc attachment movement round a
circle is non-uniform it increases under the influence of electromagnetic forces at current maximum
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
4
of a coil and decreases with its transition through zero Mean values of tangential speed of the arc
attachment were calculated on 50 complete revolutions for different regimes showed in figure 3 For
the arc current about 47 A without applied magnetic field the attachment velocity is about 25 ms and
it is rising twice when applied magnetic field density achieves 10-2
T For the arc current about 85 A
without applied magnetic field the attachment velocity is about 32 ms and it is rising from 4 to
14 ms when applied magnetic field density accordingly changes from 7x10-3
T to 20x10-3
T Numerical calculations of gas-dynamic parameters in the near electrode area for comparison the arc
attachment rotation speed and the gas flow speed for the examined modes of the plasma forming gas
feeding were carried out Considering the fact that the main flow in the back part of the channel is
formed by the cold gas submitted tangentially and that the part of the arc column situated there
occupies rather small share of the channel volume so that parameters of a cold gas flow rate (without
arc presence) were calculated in a first approximation The task was solved in the stationary statement
for the viscous compressed air The approach developed for high-speed compressible flows was
chosen Besides the Navier-Stokes equations and the continuity equations the system was
supplemented by the energy equation and a set of the empirical constants accompanying the
connection of the turbulence model (k-ε) at calculations The Figure 5 shows the calculation data
(a)
( )c
( )b
( )d
( )f
( )e
Figure 5 Plasma forming gas magnitude speed fields (ms) in the electrode channel of
the plasma torch in dependence of a total flow rate in near electrode loops of the plasma
forming gas (air) (a) - 5 gs (b) - 94 gs (c) - 122 gs in the upstream and the
downstream feeding circuits of the plasma forming gas (air) (d)-(f) - Representation of
velocity fields for different distribution of flow rates between upstream and downstream
gas feeding circuits Arrows show the arc attachment areas (d) - arc attachment is
situated in back end of electrode (e) - in the middle area and (f) - in the downstream end
Total gas flow rate - 45 gs
Figure 5 shows calculated gas velocity fields for plasma torch operation modes with different air flow rates supplied to the near electrode area On each diagram can be seen location of slower near-wall flow bounded on both sides (upstream and downstream) of a faster flow Such areas are marked by arrows in diagrams (d)-(f) The electric arc attachment of working plasma torch stabilized in these locations where the tangential velocity component makes the main contribution to the velocity magnitude (gt99) Diagrams (a)-(c) show velocity fields calculated for plasma torch operation modes with different air flow rates supplied to the near electrode area Flow rates were from 5 to 122 gs Average speeds of the arc attachment moving under the influence of a magnetic field with an
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
5
inductance of about 10-2
T were experimentally obtained for the same flow rate modes The arc current was 47 A The average speed of the arc attachment under these conditions is approximately 3 times less than the gas velocity in the near-wall electrode channel area
Figure 5 (d)-(f) shows gas magnitude velocity fields for three modes of gas feeding with different ratios of its flow rates through upstream and downstream near electrode loops The arc rotates in regions bounded on both sides of a faster flow marked by arrows In these regions the tangential velocity is more than 98 of the velocity magnitude The arrows in the diagrams (d) (e) and (f) comply with the trace of the arc at the beginning middle and end of the working electrode surface (in the longitudinal direction) Thus the position of the arc attachment can be adjusted on the working electrode surface in the longitudinal direction This allows organizing a permanent rotational and reciprocating movement of the arc in the long cylindrical electrode over its entire surface by changing the ratio of flow rates in upstream and downstream near-electrode feeding loops For represented on these diagrams modes were experimentally determined speed of the arc attachment moving under the influence of a magnetic field with an inductance of about 14x10
-3 T The average speed of the arc
attachment with a current about 84A slightly lags behind the velocity of the gas flow in the near electrode area and is about 80-90 of it In reviewing should take into account that the values of the arc attachment speed are obtained experimentally and the calculated values of flow rates are approximate and were obtained for the cold flow (excluding the arc in the working volume of the electrode) and that the real value of the flow velocity in the examined area may be different from calculated
The speed of the arc attachment longitudinal motion depends on the rate of change of the flow rate proportion Based on the results of a number of experiments it was offered for our device to organize continuous reciprocating motion of the arc attachment in the longitudinal direction (scanning) with longitudinal speed about 1 cms it is successfully realized by gas supplying system equipped with industrial automatic pressure controllers Long-term 300-hour experiments showed that longitudinal scanning of the arc attachment with its gas-dynamic and magnetic rotation allow providing the uniform wear of the electrode surface The specific erosion value is about 1-3 microgC It is 3 times less than that of the stationary AC plasma torches with the rail-type electrodes working at the same power level with arc currents about 900 A That enables production of the 1 MW industrial plasma torch with the hollow cylindrical electrode assembly with lifetime above 1000 hours at currents in the arc up to 100-200 A
Conclusion Results of experiment directed towards the increase in the lifetime characteristics of electrode units of the powerful high-voltage electric-arc AC plasma torches are presented The solution to the problem of obtainment the uniform wear of a copper hollow cylindrical electrode achieved by the controlled movement of the arc attachment along the working surface was offered Organization of gas supply in the near electrode area and application of alternating magnetic field ensured movement of arc attachment along the surface with average speed from 2 to 14 ms Arc current was about 47A and 84A Gas flow rate in near electrode area was about 45 gs The findings of influence methods on the electric arc attachment by electromagnetic and gas-dynamic forces are presented The erosion of a hollow cylindrical electrode reached only 3 microgC that enables production of the electrode assembly with life time above 1000 hours at currents in the arc up to 100-200 A
Acnowledgements
The work is supported by Russian academy of sciences and also RFBR grants 11-08-01022-a and 12-
08-00916-a Authors also express gratitude to Anton Surov for the provided data of gas-dynamic
calculations References [1] Rutberg Ph G 2003 Plasma Phys Control Fusion 45 957-69 [2] Rutberg Ph G Bratsev A N Safronov A A Surov A V Shegolev V V 2002 IEEE Transactions on
Plasma Science v30 4 ISSN 0093-3813 pp 1445-48
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
6
[3] Popov V E Bratsev A N Kuznetsov V A Shtengel S V and Ufimtsev A A 2011 Journal of Physics Conference Series 275 012015 doi1010881742-65962751012015
[4] Heberlin J Murphy A B 2008 J Phys D Appl Phys 41 053001 [5] Jeniˇsta J Takana H Nishiyama H Bartlovacutea M Aubrecht V Kˇrenek P Hrabovskacutey M Kavka
T Sember V and Maˇslacuteani A 2011 J Phys D Appl Phys 44 435204 [6] Messerle V E Ustimenko A B Askarova A S and Nagibin A O 2010 Thermophysics and
Aeromechanics Vol 17 N3 435-444 DOI 101134S0869864310030145 [7] Internet link httpwwwwestinghouse-plasmacomtechnologyplasma-torches (access date
22062012)1-14 [8] Hacala A Michon U 2009 ISPC19 Bochum Germany proceedings 39 P21404 [9] Ni Guo-Hua Meng Yue-Dong Cheng Cheng Lan Yan 2010 CHIN PHYS LETT Vol 27 No 5
055203 [10] Guohua Ni Peng Zhao Cheng Cheng Ye Song Hirotaka Toyoda and Yuedong Meng 2012
Plasma Sources Sci Technol 21 015009 [11] Rutberg Ph 2009 Physics and Technology of High-Current Discharges in Dense Gas Media and
Flows Nova Science Publishers Inc New York ISBN 978-1-60692-232-3 214 p
[12] Rutberg Ph G Kumkova I I Kuznetsov V E Popov S D Rutberg A Ph Safronov A A Shiryaev
V N and Surov A V 2007 IEEE Pulsed Power Conference (PPPS-2007) Digest of Technical
Papers 1976-2007 June 17-20 2007 Albuquerque New Mexico USA IEEE Catalog
Number 07CH37864C ISBN 1-4244-0914-4 Library of Congress 81-644315 Omnipress
Madison p 1556-59
[13] Rutberg Ph G Popov S D Safronov A A Serba E O Nakonechny Gh V 2007 XXVIII
Internatuional Conference on Phenomena in Ionized Gases (ICPIG 2007) Proceedings
Prague Czech Republic ISBN 978-80-87026-01-4 Published by Institute of Plasma Physics
AS CR vvi (4P11-07) p1762-65 [14] Rutberg Ph G Safronov A A Popov S D Surov A V and Nakonechny Gh V 2005 Plasma Phys
Control Fusion 471681-96 [15] Rutberg Ph G Lukyanov S A Kiselev A A Kuschev S A Nakonechny Gh V Nikonov A V
Popov S D Serba E O Spodobin V A and Surov A V 2011 Journal of Physics Conference Series 275 012006 doi1010881742-65962751012006
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
7
The investigation of movement dynamics of an AC electric arc
attachment along the working surface of a hollow cylindrical
electrode under the action of gas-dynamic and
electromagnetic forces
A V Surov
1 2 S D
Popov
1 2 ЕО Serba
1 G V Nakonechny
1 V А
Spodobin
1
R V Ovchinnikov1 I I Kumkova
1 S A Shabalin
1
1 Institute for Electrophysics and Electric Power of Russian Academy of Sciences
18 Dvortsovaya emb 191186 StPetersburg Russia 2 StPetersburg State Polytechnical University 29 Polytechnicheskaya 195251
StPetersburg Russia
E-mail alex_surovmailru
Abstract Stationary electric arc alternating current plasma torches are used today for
realization of plasma chemical technologies requiring relatively high energy input Waste
treatment is one these directions The paper reports on experiment results directed towards the
increase in the lifetime characteristics of electrode units of the powerful high-voltage electric-
arc AC plasma torches The solution to the problem of obtainment the uniform wear of a
copper hollow cylindrical electrode achieved by the controlled movement of the arc attachment
along the working surface was offered Organization of gas supply in the near electrode area
and application of alternating magnetic field ensured movement of arc attachment along the
surface with average speed from 2 to 14 ms Arc current was about 47 A and 84 A gas flow
rate in near electrode area was about 5 and 45 gs Due to researches on the experimental
prototype of a hollow cylindrical electrode the erosion of its material reached only 3 microgC that
enables production of the electrode assembly with life time above 1000 hours at currents in the
arc up to 100-200 A
Introduction
Currently plasmachemical technologies are actively developed for efficient use of energy resources
and implementation of ecologically safe methods for destruction and treatment of various wastes
including for the combustible syngas production [1-5] The generator of thermal plasma is a key
element of the majority of plasma chemical installations Nowadays plasma torches are also actively used in power engineering for ignition and lightning of coal boilers [6] The devices intended for
operation in large-scale industrial installations should be powerful efficiently transfer energy to the
working gas operate continuously for a long period of time and generally can operate in oxidizing media Stationary electric arc plasma torches are very promising for these purposes Westinghouse [7]
and Europlasma [8] DC plasma torches are well-developed for industrial applications The particular
attention for a number of applications deserves the models using water or steam as a plasma forming gas [5 9 10] A number of promising models of stationary AC plasma torches operating on various
gases has been developed in IEE RAS Among them are plasma torches using oxidizing media
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
Published under licence by IOP Publishing Ltd 1
(including air) powerful single-chamber three-phase plasma torches with rod electrodes [11] single-
phase and three-phase high-voltage plasma torches with power from 5 up to 100 kW with rod electrodes mounted in a separate cylindrical channels [12 13] and single-chamber three-phase plasma
torches with rail-type electrodes with operating power up to 500 kW [14] and plasma torches
working on a mixture of steam and air or another gas with power up to 100 kW were developed [15]
At present high-voltage AC plasma torches with hollow cylindrical electrodes are under development
Such plasma torches have the high arc voltage drop that enables essential current decreasing versus
low-voltage models of the same power level and accordingly increase of the electrode lifetime As a
result these devices can provide continuous operation with high power and lifetime of electrodes more
than 1000 hours Prototypes of commercial plasma torches with power 200 and 400 kW are created
The devices with power of an order 1 MW are under development This paper is devoted to
investigation of movement dynamics of an AC electric arc attachment along the working surface of a
hollow cylindrical electrode of such plasma torches The purpose of this paper is presentation of
results of the experimental researches obtained during development of new AC plasma torches
Experimental setup
The investigations were carried out at the test bench of AC plasma torches equipped with required
supply systems The test bench comprises power supply system double-loop cooling system system
of preparation and supply of plasma forming gas and system of treatment and discharge of exhaust
gases Prototypes of AC plasma torches with cylindrical (hollow) electrodes developed by IEE RAS
were used Figure 1 shows the schematic diagram of the installation The high-voltage three-phase
plasma torch is connected to the AC power supply source of industrial frequency (50 Hz) While the
plasma torch operates the arcs burn between three electrodes and have the general point behind the
nozzle exit section
Figure 1 Schematic diagram of the
experimental installation 1 - Power supply
2 - high-voltage three-phase plasma torch
with cylindrical (hollow) electrodes 3 - arc
column 4 - hollow cylindrical electrode 5 -
solenoid 6 - pipe hole for photo and video
shooting 7 - terminal for connection of the
power supply 8 and 9 - upstream and
downstream loops of tangential supply of plasma forming gas 10 - high-speed video
camera 11 - recording industrial computer
In the bottom of Figure 1 (zoomed in) is shown the schematic diagram of one of three plasma torch
channels (one of three phases) with electrode solenoid and peep hole From both sides of a hollow
electrode (upstream and downstream) are designed loops of tangential plasma forming gas supply
Rotation of the arc attachment in each of the electrodes is provided due to the tangential gas supply
and the magnetic field of the solenoid installed coaxially around the electrode The current and voltage
analogue sensing transducers are incorporated for measurement of arc currents and voltages in the
power supply The industrial computer with an acquisition boards (with bandwidth of 10 kHz per
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
2
channel) is incorporated in the measuring system for data recording Power of the plasma torch and
effective values of electric parameters are calculated on their instantaneous values There are
automated pressure regulators - the flow meters which are also connected to the industrial computer
for supply of the required plasma forming gas flow rate into the plasma torch gas inlet loops The peep
holes are provided for measurement of speed of the arc attachments on the electrode surface by means
of a high-speed video shooting Three monochrome high-speed video cameras which are a part of the
measuring system allow simultaneous synchronous recording of arc attachment movement along the
three electrodes with speed of shooting 4000 fps
Description of experiments and main results
Experiments were carried out on prototypes of the plasma torch working models Considering the
practical importance of the carried-out investigations the principal criterion for the flow rate range
selection for a gas supply mode variation and solenoid parameters for the magnetic field change were
expediency and feasibility of providing these parameters during the plasma torch work in the industrial
plants Investigations were carried out on modes of the stable arc burning in the plasma torch electrode
channels for the arc currents about 40A and 80A Longitudinal and rotary moving of the arc
attachment ndash in the axial and tangential directions was required for providing the long-lasting lifetime
of electrodes Figure 2 shows the photo of the arc attachment The photo made through the peep hole
under some angle to the axis of the plasma torch channel in order to see the electrode working surface
Figure 2 Photo of an AC electric arc attachment
on the working surface of the cylindrical electrode
shutter speed 14000 s
The internal part of the cylindrical electrode surface where during the plasma torch work the arc
attachment leaves the trace we will call a working surface The arc attachment position on the
electrode working surface in the longitudinal direction was possible to set by regulation of the flow
rates in near-electrode loops of the plasma forming gas supply The rotation speed of the arc
attachment depends both on the gas supply mode and on characteristics of the impressed magnetic
field
The AC arc attachment rotates under the action of the gas-dynamic forces sliding over the
electrode working surface during the plasma torch work Plasma of the arc column does not have
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
3
enough time to relax at the current zero crossing and the arc is ignited in the same channel in the each
following half-period The solenoid which is forming a longitudinal magnetic field in the hollow
electrode volume is coaxially put on the electrode for the intensification of the arc attachment
rotation The solenoid coil is powered from the AC power supply so that at the arc current polarity
changing the current direction in the coil changes Thus despite of the arc current polarity changing
the force direction acting on the arc attachment and promoting the intensification of its rotational
movement remains the same The magnitude of force acting on the charged particles of the arc column
in the arc attachment area changes due to the sinusoidal change of the current in the coil This force
reaches the maximum value at the peak arc current and decreases at the moment of the current
transition through zero The connection of the AC coil in the opposite direction can cause the braking
or even arc attachment moving towards to the gas flow which is undesirable as it leads to increase of
the electrode material erosion and the reduction of its lifetime
The magnetic field produced by a solenoid in the electrode channel was obtained using computer
simulation Figure 4 shows the schematic diagram of the electrode with the solenoid (a) and
characteristic graphs of distribution of value of magnetic inductance on a working surface of an
electrode in the longitudinal direction (b) and its distributions along the diameter of the electrode
chamber (c) Values of magnetic inductance during the moments of time matching to maxima of
currents in the solenoid windings for the points of space laying on lines L and D are built in the
graphs Line L represents the generating line of the working surface and line D coincides with the
diameter
A
L
D
A
L
D
(a)
00 02 04 06 08 lL
4
8
12
16
20
B10-3
T (b)
00 02 04 06 08 dD
4
8
12
16
20
B10-3T
1
2
3
4
5
(c)
Figure 3 Schematic diagram of the hollow cylindrical electrode with solenoid (a) and characteristic
graphs of distribution of the value of the magnetic inductance in the electrode channel at the moment
of current maximum in the solenoid windings Lines D and L ndash lines along which are calculated the
values of magnetic inductance presented in graphs (b) - longitudinal distribution of the magnetic
inductance along the electrode working surface (c) - distribution of the magnetic inductance on the
diameter of the electrode chamber Point A belongs to ring area with the maximum magnetic field
density on the electrode working surface Curve 1 shows magnetic inductance for plasma torch
working with arc current of 47 A curves 2-5 correspond the plasma torch working modes with arc
current of 85 A
Analysis of materials of a high-speed video shooting of the arc attachment movement along the
electrode surface shows dependences of the arc attachment versus plasma torch operating parameters
and characteristics of applied magnetic field Shooting was carried out through the peep holes located
in a back part of the electrode channel with use of High Speed Video Cameras ldquoCitius Imaging C100
Centuriordquo with a speed 4000 fps and exposure 2 micros Speed of the arc attachment movement round a
circle is non-uniform it increases under the influence of electromagnetic forces at current maximum
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
4
of a coil and decreases with its transition through zero Mean values of tangential speed of the arc
attachment were calculated on 50 complete revolutions for different regimes showed in figure 3 For
the arc current about 47 A without applied magnetic field the attachment velocity is about 25 ms and
it is rising twice when applied magnetic field density achieves 10-2
T For the arc current about 85 A
without applied magnetic field the attachment velocity is about 32 ms and it is rising from 4 to
14 ms when applied magnetic field density accordingly changes from 7x10-3
T to 20x10-3
T Numerical calculations of gas-dynamic parameters in the near electrode area for comparison the arc
attachment rotation speed and the gas flow speed for the examined modes of the plasma forming gas
feeding were carried out Considering the fact that the main flow in the back part of the channel is
formed by the cold gas submitted tangentially and that the part of the arc column situated there
occupies rather small share of the channel volume so that parameters of a cold gas flow rate (without
arc presence) were calculated in a first approximation The task was solved in the stationary statement
for the viscous compressed air The approach developed for high-speed compressible flows was
chosen Besides the Navier-Stokes equations and the continuity equations the system was
supplemented by the energy equation and a set of the empirical constants accompanying the
connection of the turbulence model (k-ε) at calculations The Figure 5 shows the calculation data
(a)
( )c
( )b
( )d
( )f
( )e
Figure 5 Plasma forming gas magnitude speed fields (ms) in the electrode channel of
the plasma torch in dependence of a total flow rate in near electrode loops of the plasma
forming gas (air) (a) - 5 gs (b) - 94 gs (c) - 122 gs in the upstream and the
downstream feeding circuits of the plasma forming gas (air) (d)-(f) - Representation of
velocity fields for different distribution of flow rates between upstream and downstream
gas feeding circuits Arrows show the arc attachment areas (d) - arc attachment is
situated in back end of electrode (e) - in the middle area and (f) - in the downstream end
Total gas flow rate - 45 gs
Figure 5 shows calculated gas velocity fields for plasma torch operation modes with different air flow rates supplied to the near electrode area On each diagram can be seen location of slower near-wall flow bounded on both sides (upstream and downstream) of a faster flow Such areas are marked by arrows in diagrams (d)-(f) The electric arc attachment of working plasma torch stabilized in these locations where the tangential velocity component makes the main contribution to the velocity magnitude (gt99) Diagrams (a)-(c) show velocity fields calculated for plasma torch operation modes with different air flow rates supplied to the near electrode area Flow rates were from 5 to 122 gs Average speeds of the arc attachment moving under the influence of a magnetic field with an
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
5
inductance of about 10-2
T were experimentally obtained for the same flow rate modes The arc current was 47 A The average speed of the arc attachment under these conditions is approximately 3 times less than the gas velocity in the near-wall electrode channel area
Figure 5 (d)-(f) shows gas magnitude velocity fields for three modes of gas feeding with different ratios of its flow rates through upstream and downstream near electrode loops The arc rotates in regions bounded on both sides of a faster flow marked by arrows In these regions the tangential velocity is more than 98 of the velocity magnitude The arrows in the diagrams (d) (e) and (f) comply with the trace of the arc at the beginning middle and end of the working electrode surface (in the longitudinal direction) Thus the position of the arc attachment can be adjusted on the working electrode surface in the longitudinal direction This allows organizing a permanent rotational and reciprocating movement of the arc in the long cylindrical electrode over its entire surface by changing the ratio of flow rates in upstream and downstream near-electrode feeding loops For represented on these diagrams modes were experimentally determined speed of the arc attachment moving under the influence of a magnetic field with an inductance of about 14x10
-3 T The average speed of the arc
attachment with a current about 84A slightly lags behind the velocity of the gas flow in the near electrode area and is about 80-90 of it In reviewing should take into account that the values of the arc attachment speed are obtained experimentally and the calculated values of flow rates are approximate and were obtained for the cold flow (excluding the arc in the working volume of the electrode) and that the real value of the flow velocity in the examined area may be different from calculated
The speed of the arc attachment longitudinal motion depends on the rate of change of the flow rate proportion Based on the results of a number of experiments it was offered for our device to organize continuous reciprocating motion of the arc attachment in the longitudinal direction (scanning) with longitudinal speed about 1 cms it is successfully realized by gas supplying system equipped with industrial automatic pressure controllers Long-term 300-hour experiments showed that longitudinal scanning of the arc attachment with its gas-dynamic and magnetic rotation allow providing the uniform wear of the electrode surface The specific erosion value is about 1-3 microgC It is 3 times less than that of the stationary AC plasma torches with the rail-type electrodes working at the same power level with arc currents about 900 A That enables production of the 1 MW industrial plasma torch with the hollow cylindrical electrode assembly with lifetime above 1000 hours at currents in the arc up to 100-200 A
Conclusion Results of experiment directed towards the increase in the lifetime characteristics of electrode units of the powerful high-voltage electric-arc AC plasma torches are presented The solution to the problem of obtainment the uniform wear of a copper hollow cylindrical electrode achieved by the controlled movement of the arc attachment along the working surface was offered Organization of gas supply in the near electrode area and application of alternating magnetic field ensured movement of arc attachment along the surface with average speed from 2 to 14 ms Arc current was about 47A and 84A Gas flow rate in near electrode area was about 45 gs The findings of influence methods on the electric arc attachment by electromagnetic and gas-dynamic forces are presented The erosion of a hollow cylindrical electrode reached only 3 microgC that enables production of the electrode assembly with life time above 1000 hours at currents in the arc up to 100-200 A
Acnowledgements
The work is supported by Russian academy of sciences and also RFBR grants 11-08-01022-a and 12-
08-00916-a Authors also express gratitude to Anton Surov for the provided data of gas-dynamic
calculations References [1] Rutberg Ph G 2003 Plasma Phys Control Fusion 45 957-69 [2] Rutberg Ph G Bratsev A N Safronov A A Surov A V Shegolev V V 2002 IEEE Transactions on
Plasma Science v30 4 ISSN 0093-3813 pp 1445-48
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
6
[3] Popov V E Bratsev A N Kuznetsov V A Shtengel S V and Ufimtsev A A 2011 Journal of Physics Conference Series 275 012015 doi1010881742-65962751012015
[4] Heberlin J Murphy A B 2008 J Phys D Appl Phys 41 053001 [5] Jeniˇsta J Takana H Nishiyama H Bartlovacutea M Aubrecht V Kˇrenek P Hrabovskacutey M Kavka
T Sember V and Maˇslacuteani A 2011 J Phys D Appl Phys 44 435204 [6] Messerle V E Ustimenko A B Askarova A S and Nagibin A O 2010 Thermophysics and
Aeromechanics Vol 17 N3 435-444 DOI 101134S0869864310030145 [7] Internet link httpwwwwestinghouse-plasmacomtechnologyplasma-torches (access date
22062012)1-14 [8] Hacala A Michon U 2009 ISPC19 Bochum Germany proceedings 39 P21404 [9] Ni Guo-Hua Meng Yue-Dong Cheng Cheng Lan Yan 2010 CHIN PHYS LETT Vol 27 No 5
055203 [10] Guohua Ni Peng Zhao Cheng Cheng Ye Song Hirotaka Toyoda and Yuedong Meng 2012
Plasma Sources Sci Technol 21 015009 [11] Rutberg Ph 2009 Physics and Technology of High-Current Discharges in Dense Gas Media and
Flows Nova Science Publishers Inc New York ISBN 978-1-60692-232-3 214 p
[12] Rutberg Ph G Kumkova I I Kuznetsov V E Popov S D Rutberg A Ph Safronov A A Shiryaev
V N and Surov A V 2007 IEEE Pulsed Power Conference (PPPS-2007) Digest of Technical
Papers 1976-2007 June 17-20 2007 Albuquerque New Mexico USA IEEE Catalog
Number 07CH37864C ISBN 1-4244-0914-4 Library of Congress 81-644315 Omnipress
Madison p 1556-59
[13] Rutberg Ph G Popov S D Safronov A A Serba E O Nakonechny Gh V 2007 XXVIII
Internatuional Conference on Phenomena in Ionized Gases (ICPIG 2007) Proceedings
Prague Czech Republic ISBN 978-80-87026-01-4 Published by Institute of Plasma Physics
AS CR vvi (4P11-07) p1762-65 [14] Rutberg Ph G Safronov A A Popov S D Surov A V and Nakonechny Gh V 2005 Plasma Phys
Control Fusion 471681-96 [15] Rutberg Ph G Lukyanov S A Kiselev A A Kuschev S A Nakonechny Gh V Nikonov A V
Popov S D Serba E O Spodobin V A and Surov A V 2011 Journal of Physics Conference Series 275 012006 doi1010881742-65962751012006
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
7
(including air) powerful single-chamber three-phase plasma torches with rod electrodes [11] single-
phase and three-phase high-voltage plasma torches with power from 5 up to 100 kW with rod electrodes mounted in a separate cylindrical channels [12 13] and single-chamber three-phase plasma
torches with rail-type electrodes with operating power up to 500 kW [14] and plasma torches
working on a mixture of steam and air or another gas with power up to 100 kW were developed [15]
At present high-voltage AC plasma torches with hollow cylindrical electrodes are under development
Such plasma torches have the high arc voltage drop that enables essential current decreasing versus
low-voltage models of the same power level and accordingly increase of the electrode lifetime As a
result these devices can provide continuous operation with high power and lifetime of electrodes more
than 1000 hours Prototypes of commercial plasma torches with power 200 and 400 kW are created
The devices with power of an order 1 MW are under development This paper is devoted to
investigation of movement dynamics of an AC electric arc attachment along the working surface of a
hollow cylindrical electrode of such plasma torches The purpose of this paper is presentation of
results of the experimental researches obtained during development of new AC plasma torches
Experimental setup
The investigations were carried out at the test bench of AC plasma torches equipped with required
supply systems The test bench comprises power supply system double-loop cooling system system
of preparation and supply of plasma forming gas and system of treatment and discharge of exhaust
gases Prototypes of AC plasma torches with cylindrical (hollow) electrodes developed by IEE RAS
were used Figure 1 shows the schematic diagram of the installation The high-voltage three-phase
plasma torch is connected to the AC power supply source of industrial frequency (50 Hz) While the
plasma torch operates the arcs burn between three electrodes and have the general point behind the
nozzle exit section
Figure 1 Schematic diagram of the
experimental installation 1 - Power supply
2 - high-voltage three-phase plasma torch
with cylindrical (hollow) electrodes 3 - arc
column 4 - hollow cylindrical electrode 5 -
solenoid 6 - pipe hole for photo and video
shooting 7 - terminal for connection of the
power supply 8 and 9 - upstream and
downstream loops of tangential supply of plasma forming gas 10 - high-speed video
camera 11 - recording industrial computer
In the bottom of Figure 1 (zoomed in) is shown the schematic diagram of one of three plasma torch
channels (one of three phases) with electrode solenoid and peep hole From both sides of a hollow
electrode (upstream and downstream) are designed loops of tangential plasma forming gas supply
Rotation of the arc attachment in each of the electrodes is provided due to the tangential gas supply
and the magnetic field of the solenoid installed coaxially around the electrode The current and voltage
analogue sensing transducers are incorporated for measurement of arc currents and voltages in the
power supply The industrial computer with an acquisition boards (with bandwidth of 10 kHz per
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
2
channel) is incorporated in the measuring system for data recording Power of the plasma torch and
effective values of electric parameters are calculated on their instantaneous values There are
automated pressure regulators - the flow meters which are also connected to the industrial computer
for supply of the required plasma forming gas flow rate into the plasma torch gas inlet loops The peep
holes are provided for measurement of speed of the arc attachments on the electrode surface by means
of a high-speed video shooting Three monochrome high-speed video cameras which are a part of the
measuring system allow simultaneous synchronous recording of arc attachment movement along the
three electrodes with speed of shooting 4000 fps
Description of experiments and main results
Experiments were carried out on prototypes of the plasma torch working models Considering the
practical importance of the carried-out investigations the principal criterion for the flow rate range
selection for a gas supply mode variation and solenoid parameters for the magnetic field change were
expediency and feasibility of providing these parameters during the plasma torch work in the industrial
plants Investigations were carried out on modes of the stable arc burning in the plasma torch electrode
channels for the arc currents about 40A and 80A Longitudinal and rotary moving of the arc
attachment ndash in the axial and tangential directions was required for providing the long-lasting lifetime
of electrodes Figure 2 shows the photo of the arc attachment The photo made through the peep hole
under some angle to the axis of the plasma torch channel in order to see the electrode working surface
Figure 2 Photo of an AC electric arc attachment
on the working surface of the cylindrical electrode
shutter speed 14000 s
The internal part of the cylindrical electrode surface where during the plasma torch work the arc
attachment leaves the trace we will call a working surface The arc attachment position on the
electrode working surface in the longitudinal direction was possible to set by regulation of the flow
rates in near-electrode loops of the plasma forming gas supply The rotation speed of the arc
attachment depends both on the gas supply mode and on characteristics of the impressed magnetic
field
The AC arc attachment rotates under the action of the gas-dynamic forces sliding over the
electrode working surface during the plasma torch work Plasma of the arc column does not have
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
3
enough time to relax at the current zero crossing and the arc is ignited in the same channel in the each
following half-period The solenoid which is forming a longitudinal magnetic field in the hollow
electrode volume is coaxially put on the electrode for the intensification of the arc attachment
rotation The solenoid coil is powered from the AC power supply so that at the arc current polarity
changing the current direction in the coil changes Thus despite of the arc current polarity changing
the force direction acting on the arc attachment and promoting the intensification of its rotational
movement remains the same The magnitude of force acting on the charged particles of the arc column
in the arc attachment area changes due to the sinusoidal change of the current in the coil This force
reaches the maximum value at the peak arc current and decreases at the moment of the current
transition through zero The connection of the AC coil in the opposite direction can cause the braking
or even arc attachment moving towards to the gas flow which is undesirable as it leads to increase of
the electrode material erosion and the reduction of its lifetime
The magnetic field produced by a solenoid in the electrode channel was obtained using computer
simulation Figure 4 shows the schematic diagram of the electrode with the solenoid (a) and
characteristic graphs of distribution of value of magnetic inductance on a working surface of an
electrode in the longitudinal direction (b) and its distributions along the diameter of the electrode
chamber (c) Values of magnetic inductance during the moments of time matching to maxima of
currents in the solenoid windings for the points of space laying on lines L and D are built in the
graphs Line L represents the generating line of the working surface and line D coincides with the
diameter
A
L
D
A
L
D
(a)
00 02 04 06 08 lL
4
8
12
16
20
B10-3
T (b)
00 02 04 06 08 dD
4
8
12
16
20
B10-3T
1
2
3
4
5
(c)
Figure 3 Schematic diagram of the hollow cylindrical electrode with solenoid (a) and characteristic
graphs of distribution of the value of the magnetic inductance in the electrode channel at the moment
of current maximum in the solenoid windings Lines D and L ndash lines along which are calculated the
values of magnetic inductance presented in graphs (b) - longitudinal distribution of the magnetic
inductance along the electrode working surface (c) - distribution of the magnetic inductance on the
diameter of the electrode chamber Point A belongs to ring area with the maximum magnetic field
density on the electrode working surface Curve 1 shows magnetic inductance for plasma torch
working with arc current of 47 A curves 2-5 correspond the plasma torch working modes with arc
current of 85 A
Analysis of materials of a high-speed video shooting of the arc attachment movement along the
electrode surface shows dependences of the arc attachment versus plasma torch operating parameters
and characteristics of applied magnetic field Shooting was carried out through the peep holes located
in a back part of the electrode channel with use of High Speed Video Cameras ldquoCitius Imaging C100
Centuriordquo with a speed 4000 fps and exposure 2 micros Speed of the arc attachment movement round a
circle is non-uniform it increases under the influence of electromagnetic forces at current maximum
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
4
of a coil and decreases with its transition through zero Mean values of tangential speed of the arc
attachment were calculated on 50 complete revolutions for different regimes showed in figure 3 For
the arc current about 47 A without applied magnetic field the attachment velocity is about 25 ms and
it is rising twice when applied magnetic field density achieves 10-2
T For the arc current about 85 A
without applied magnetic field the attachment velocity is about 32 ms and it is rising from 4 to
14 ms when applied magnetic field density accordingly changes from 7x10-3
T to 20x10-3
T Numerical calculations of gas-dynamic parameters in the near electrode area for comparison the arc
attachment rotation speed and the gas flow speed for the examined modes of the plasma forming gas
feeding were carried out Considering the fact that the main flow in the back part of the channel is
formed by the cold gas submitted tangentially and that the part of the arc column situated there
occupies rather small share of the channel volume so that parameters of a cold gas flow rate (without
arc presence) were calculated in a first approximation The task was solved in the stationary statement
for the viscous compressed air The approach developed for high-speed compressible flows was
chosen Besides the Navier-Stokes equations and the continuity equations the system was
supplemented by the energy equation and a set of the empirical constants accompanying the
connection of the turbulence model (k-ε) at calculations The Figure 5 shows the calculation data
(a)
( )c
( )b
( )d
( )f
( )e
Figure 5 Plasma forming gas magnitude speed fields (ms) in the electrode channel of
the plasma torch in dependence of a total flow rate in near electrode loops of the plasma
forming gas (air) (a) - 5 gs (b) - 94 gs (c) - 122 gs in the upstream and the
downstream feeding circuits of the plasma forming gas (air) (d)-(f) - Representation of
velocity fields for different distribution of flow rates between upstream and downstream
gas feeding circuits Arrows show the arc attachment areas (d) - arc attachment is
situated in back end of electrode (e) - in the middle area and (f) - in the downstream end
Total gas flow rate - 45 gs
Figure 5 shows calculated gas velocity fields for plasma torch operation modes with different air flow rates supplied to the near electrode area On each diagram can be seen location of slower near-wall flow bounded on both sides (upstream and downstream) of a faster flow Such areas are marked by arrows in diagrams (d)-(f) The electric arc attachment of working plasma torch stabilized in these locations where the tangential velocity component makes the main contribution to the velocity magnitude (gt99) Diagrams (a)-(c) show velocity fields calculated for plasma torch operation modes with different air flow rates supplied to the near electrode area Flow rates were from 5 to 122 gs Average speeds of the arc attachment moving under the influence of a magnetic field with an
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
5
inductance of about 10-2
T were experimentally obtained for the same flow rate modes The arc current was 47 A The average speed of the arc attachment under these conditions is approximately 3 times less than the gas velocity in the near-wall electrode channel area
Figure 5 (d)-(f) shows gas magnitude velocity fields for three modes of gas feeding with different ratios of its flow rates through upstream and downstream near electrode loops The arc rotates in regions bounded on both sides of a faster flow marked by arrows In these regions the tangential velocity is more than 98 of the velocity magnitude The arrows in the diagrams (d) (e) and (f) comply with the trace of the arc at the beginning middle and end of the working electrode surface (in the longitudinal direction) Thus the position of the arc attachment can be adjusted on the working electrode surface in the longitudinal direction This allows organizing a permanent rotational and reciprocating movement of the arc in the long cylindrical electrode over its entire surface by changing the ratio of flow rates in upstream and downstream near-electrode feeding loops For represented on these diagrams modes were experimentally determined speed of the arc attachment moving under the influence of a magnetic field with an inductance of about 14x10
-3 T The average speed of the arc
attachment with a current about 84A slightly lags behind the velocity of the gas flow in the near electrode area and is about 80-90 of it In reviewing should take into account that the values of the arc attachment speed are obtained experimentally and the calculated values of flow rates are approximate and were obtained for the cold flow (excluding the arc in the working volume of the electrode) and that the real value of the flow velocity in the examined area may be different from calculated
The speed of the arc attachment longitudinal motion depends on the rate of change of the flow rate proportion Based on the results of a number of experiments it was offered for our device to organize continuous reciprocating motion of the arc attachment in the longitudinal direction (scanning) with longitudinal speed about 1 cms it is successfully realized by gas supplying system equipped with industrial automatic pressure controllers Long-term 300-hour experiments showed that longitudinal scanning of the arc attachment with its gas-dynamic and magnetic rotation allow providing the uniform wear of the electrode surface The specific erosion value is about 1-3 microgC It is 3 times less than that of the stationary AC plasma torches with the rail-type electrodes working at the same power level with arc currents about 900 A That enables production of the 1 MW industrial plasma torch with the hollow cylindrical electrode assembly with lifetime above 1000 hours at currents in the arc up to 100-200 A
Conclusion Results of experiment directed towards the increase in the lifetime characteristics of electrode units of the powerful high-voltage electric-arc AC plasma torches are presented The solution to the problem of obtainment the uniform wear of a copper hollow cylindrical electrode achieved by the controlled movement of the arc attachment along the working surface was offered Organization of gas supply in the near electrode area and application of alternating magnetic field ensured movement of arc attachment along the surface with average speed from 2 to 14 ms Arc current was about 47A and 84A Gas flow rate in near electrode area was about 45 gs The findings of influence methods on the electric arc attachment by electromagnetic and gas-dynamic forces are presented The erosion of a hollow cylindrical electrode reached only 3 microgC that enables production of the electrode assembly with life time above 1000 hours at currents in the arc up to 100-200 A
Acnowledgements
The work is supported by Russian academy of sciences and also RFBR grants 11-08-01022-a and 12-
08-00916-a Authors also express gratitude to Anton Surov for the provided data of gas-dynamic
calculations References [1] Rutberg Ph G 2003 Plasma Phys Control Fusion 45 957-69 [2] Rutberg Ph G Bratsev A N Safronov A A Surov A V Shegolev V V 2002 IEEE Transactions on
Plasma Science v30 4 ISSN 0093-3813 pp 1445-48
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
6
[3] Popov V E Bratsev A N Kuznetsov V A Shtengel S V and Ufimtsev A A 2011 Journal of Physics Conference Series 275 012015 doi1010881742-65962751012015
[4] Heberlin J Murphy A B 2008 J Phys D Appl Phys 41 053001 [5] Jeniˇsta J Takana H Nishiyama H Bartlovacutea M Aubrecht V Kˇrenek P Hrabovskacutey M Kavka
T Sember V and Maˇslacuteani A 2011 J Phys D Appl Phys 44 435204 [6] Messerle V E Ustimenko A B Askarova A S and Nagibin A O 2010 Thermophysics and
Aeromechanics Vol 17 N3 435-444 DOI 101134S0869864310030145 [7] Internet link httpwwwwestinghouse-plasmacomtechnologyplasma-torches (access date
22062012)1-14 [8] Hacala A Michon U 2009 ISPC19 Bochum Germany proceedings 39 P21404 [9] Ni Guo-Hua Meng Yue-Dong Cheng Cheng Lan Yan 2010 CHIN PHYS LETT Vol 27 No 5
055203 [10] Guohua Ni Peng Zhao Cheng Cheng Ye Song Hirotaka Toyoda and Yuedong Meng 2012
Plasma Sources Sci Technol 21 015009 [11] Rutberg Ph 2009 Physics and Technology of High-Current Discharges in Dense Gas Media and
Flows Nova Science Publishers Inc New York ISBN 978-1-60692-232-3 214 p
[12] Rutberg Ph G Kumkova I I Kuznetsov V E Popov S D Rutberg A Ph Safronov A A Shiryaev
V N and Surov A V 2007 IEEE Pulsed Power Conference (PPPS-2007) Digest of Technical
Papers 1976-2007 June 17-20 2007 Albuquerque New Mexico USA IEEE Catalog
Number 07CH37864C ISBN 1-4244-0914-4 Library of Congress 81-644315 Omnipress
Madison p 1556-59
[13] Rutberg Ph G Popov S D Safronov A A Serba E O Nakonechny Gh V 2007 XXVIII
Internatuional Conference on Phenomena in Ionized Gases (ICPIG 2007) Proceedings
Prague Czech Republic ISBN 978-80-87026-01-4 Published by Institute of Plasma Physics
AS CR vvi (4P11-07) p1762-65 [14] Rutberg Ph G Safronov A A Popov S D Surov A V and Nakonechny Gh V 2005 Plasma Phys
Control Fusion 471681-96 [15] Rutberg Ph G Lukyanov S A Kiselev A A Kuschev S A Nakonechny Gh V Nikonov A V
Popov S D Serba E O Spodobin V A and Surov A V 2011 Journal of Physics Conference Series 275 012006 doi1010881742-65962751012006
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
7
channel) is incorporated in the measuring system for data recording Power of the plasma torch and
effective values of electric parameters are calculated on their instantaneous values There are
automated pressure regulators - the flow meters which are also connected to the industrial computer
for supply of the required plasma forming gas flow rate into the plasma torch gas inlet loops The peep
holes are provided for measurement of speed of the arc attachments on the electrode surface by means
of a high-speed video shooting Three monochrome high-speed video cameras which are a part of the
measuring system allow simultaneous synchronous recording of arc attachment movement along the
three electrodes with speed of shooting 4000 fps
Description of experiments and main results
Experiments were carried out on prototypes of the plasma torch working models Considering the
practical importance of the carried-out investigations the principal criterion for the flow rate range
selection for a gas supply mode variation and solenoid parameters for the magnetic field change were
expediency and feasibility of providing these parameters during the plasma torch work in the industrial
plants Investigations were carried out on modes of the stable arc burning in the plasma torch electrode
channels for the arc currents about 40A and 80A Longitudinal and rotary moving of the arc
attachment ndash in the axial and tangential directions was required for providing the long-lasting lifetime
of electrodes Figure 2 shows the photo of the arc attachment The photo made through the peep hole
under some angle to the axis of the plasma torch channel in order to see the electrode working surface
Figure 2 Photo of an AC electric arc attachment
on the working surface of the cylindrical electrode
shutter speed 14000 s
The internal part of the cylindrical electrode surface where during the plasma torch work the arc
attachment leaves the trace we will call a working surface The arc attachment position on the
electrode working surface in the longitudinal direction was possible to set by regulation of the flow
rates in near-electrode loops of the plasma forming gas supply The rotation speed of the arc
attachment depends both on the gas supply mode and on characteristics of the impressed magnetic
field
The AC arc attachment rotates under the action of the gas-dynamic forces sliding over the
electrode working surface during the plasma torch work Plasma of the arc column does not have
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
3
enough time to relax at the current zero crossing and the arc is ignited in the same channel in the each
following half-period The solenoid which is forming a longitudinal magnetic field in the hollow
electrode volume is coaxially put on the electrode for the intensification of the arc attachment
rotation The solenoid coil is powered from the AC power supply so that at the arc current polarity
changing the current direction in the coil changes Thus despite of the arc current polarity changing
the force direction acting on the arc attachment and promoting the intensification of its rotational
movement remains the same The magnitude of force acting on the charged particles of the arc column
in the arc attachment area changes due to the sinusoidal change of the current in the coil This force
reaches the maximum value at the peak arc current and decreases at the moment of the current
transition through zero The connection of the AC coil in the opposite direction can cause the braking
or even arc attachment moving towards to the gas flow which is undesirable as it leads to increase of
the electrode material erosion and the reduction of its lifetime
The magnetic field produced by a solenoid in the electrode channel was obtained using computer
simulation Figure 4 shows the schematic diagram of the electrode with the solenoid (a) and
characteristic graphs of distribution of value of magnetic inductance on a working surface of an
electrode in the longitudinal direction (b) and its distributions along the diameter of the electrode
chamber (c) Values of magnetic inductance during the moments of time matching to maxima of
currents in the solenoid windings for the points of space laying on lines L and D are built in the
graphs Line L represents the generating line of the working surface and line D coincides with the
diameter
A
L
D
A
L
D
(a)
00 02 04 06 08 lL
4
8
12
16
20
B10-3
T (b)
00 02 04 06 08 dD
4
8
12
16
20
B10-3T
1
2
3
4
5
(c)
Figure 3 Schematic diagram of the hollow cylindrical electrode with solenoid (a) and characteristic
graphs of distribution of the value of the magnetic inductance in the electrode channel at the moment
of current maximum in the solenoid windings Lines D and L ndash lines along which are calculated the
values of magnetic inductance presented in graphs (b) - longitudinal distribution of the magnetic
inductance along the electrode working surface (c) - distribution of the magnetic inductance on the
diameter of the electrode chamber Point A belongs to ring area with the maximum magnetic field
density on the electrode working surface Curve 1 shows magnetic inductance for plasma torch
working with arc current of 47 A curves 2-5 correspond the plasma torch working modes with arc
current of 85 A
Analysis of materials of a high-speed video shooting of the arc attachment movement along the
electrode surface shows dependences of the arc attachment versus plasma torch operating parameters
and characteristics of applied magnetic field Shooting was carried out through the peep holes located
in a back part of the electrode channel with use of High Speed Video Cameras ldquoCitius Imaging C100
Centuriordquo with a speed 4000 fps and exposure 2 micros Speed of the arc attachment movement round a
circle is non-uniform it increases under the influence of electromagnetic forces at current maximum
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
4
of a coil and decreases with its transition through zero Mean values of tangential speed of the arc
attachment were calculated on 50 complete revolutions for different regimes showed in figure 3 For
the arc current about 47 A without applied magnetic field the attachment velocity is about 25 ms and
it is rising twice when applied magnetic field density achieves 10-2
T For the arc current about 85 A
without applied magnetic field the attachment velocity is about 32 ms and it is rising from 4 to
14 ms when applied magnetic field density accordingly changes from 7x10-3
T to 20x10-3
T Numerical calculations of gas-dynamic parameters in the near electrode area for comparison the arc
attachment rotation speed and the gas flow speed for the examined modes of the plasma forming gas
feeding were carried out Considering the fact that the main flow in the back part of the channel is
formed by the cold gas submitted tangentially and that the part of the arc column situated there
occupies rather small share of the channel volume so that parameters of a cold gas flow rate (without
arc presence) were calculated in a first approximation The task was solved in the stationary statement
for the viscous compressed air The approach developed for high-speed compressible flows was
chosen Besides the Navier-Stokes equations and the continuity equations the system was
supplemented by the energy equation and a set of the empirical constants accompanying the
connection of the turbulence model (k-ε) at calculations The Figure 5 shows the calculation data
(a)
( )c
( )b
( )d
( )f
( )e
Figure 5 Plasma forming gas magnitude speed fields (ms) in the electrode channel of
the plasma torch in dependence of a total flow rate in near electrode loops of the plasma
forming gas (air) (a) - 5 gs (b) - 94 gs (c) - 122 gs in the upstream and the
downstream feeding circuits of the plasma forming gas (air) (d)-(f) - Representation of
velocity fields for different distribution of flow rates between upstream and downstream
gas feeding circuits Arrows show the arc attachment areas (d) - arc attachment is
situated in back end of electrode (e) - in the middle area and (f) - in the downstream end
Total gas flow rate - 45 gs
Figure 5 shows calculated gas velocity fields for plasma torch operation modes with different air flow rates supplied to the near electrode area On each diagram can be seen location of slower near-wall flow bounded on both sides (upstream and downstream) of a faster flow Such areas are marked by arrows in diagrams (d)-(f) The electric arc attachment of working plasma torch stabilized in these locations where the tangential velocity component makes the main contribution to the velocity magnitude (gt99) Diagrams (a)-(c) show velocity fields calculated for plasma torch operation modes with different air flow rates supplied to the near electrode area Flow rates were from 5 to 122 gs Average speeds of the arc attachment moving under the influence of a magnetic field with an
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
5
inductance of about 10-2
T were experimentally obtained for the same flow rate modes The arc current was 47 A The average speed of the arc attachment under these conditions is approximately 3 times less than the gas velocity in the near-wall electrode channel area
Figure 5 (d)-(f) shows gas magnitude velocity fields for three modes of gas feeding with different ratios of its flow rates through upstream and downstream near electrode loops The arc rotates in regions bounded on both sides of a faster flow marked by arrows In these regions the tangential velocity is more than 98 of the velocity magnitude The arrows in the diagrams (d) (e) and (f) comply with the trace of the arc at the beginning middle and end of the working electrode surface (in the longitudinal direction) Thus the position of the arc attachment can be adjusted on the working electrode surface in the longitudinal direction This allows organizing a permanent rotational and reciprocating movement of the arc in the long cylindrical electrode over its entire surface by changing the ratio of flow rates in upstream and downstream near-electrode feeding loops For represented on these diagrams modes were experimentally determined speed of the arc attachment moving under the influence of a magnetic field with an inductance of about 14x10
-3 T The average speed of the arc
attachment with a current about 84A slightly lags behind the velocity of the gas flow in the near electrode area and is about 80-90 of it In reviewing should take into account that the values of the arc attachment speed are obtained experimentally and the calculated values of flow rates are approximate and were obtained for the cold flow (excluding the arc in the working volume of the electrode) and that the real value of the flow velocity in the examined area may be different from calculated
The speed of the arc attachment longitudinal motion depends on the rate of change of the flow rate proportion Based on the results of a number of experiments it was offered for our device to organize continuous reciprocating motion of the arc attachment in the longitudinal direction (scanning) with longitudinal speed about 1 cms it is successfully realized by gas supplying system equipped with industrial automatic pressure controllers Long-term 300-hour experiments showed that longitudinal scanning of the arc attachment with its gas-dynamic and magnetic rotation allow providing the uniform wear of the electrode surface The specific erosion value is about 1-3 microgC It is 3 times less than that of the stationary AC plasma torches with the rail-type electrodes working at the same power level with arc currents about 900 A That enables production of the 1 MW industrial plasma torch with the hollow cylindrical electrode assembly with lifetime above 1000 hours at currents in the arc up to 100-200 A
Conclusion Results of experiment directed towards the increase in the lifetime characteristics of electrode units of the powerful high-voltage electric-arc AC plasma torches are presented The solution to the problem of obtainment the uniform wear of a copper hollow cylindrical electrode achieved by the controlled movement of the arc attachment along the working surface was offered Organization of gas supply in the near electrode area and application of alternating magnetic field ensured movement of arc attachment along the surface with average speed from 2 to 14 ms Arc current was about 47A and 84A Gas flow rate in near electrode area was about 45 gs The findings of influence methods on the electric arc attachment by electromagnetic and gas-dynamic forces are presented The erosion of a hollow cylindrical electrode reached only 3 microgC that enables production of the electrode assembly with life time above 1000 hours at currents in the arc up to 100-200 A
Acnowledgements
The work is supported by Russian academy of sciences and also RFBR grants 11-08-01022-a and 12-
08-00916-a Authors also express gratitude to Anton Surov for the provided data of gas-dynamic
calculations References [1] Rutberg Ph G 2003 Plasma Phys Control Fusion 45 957-69 [2] Rutberg Ph G Bratsev A N Safronov A A Surov A V Shegolev V V 2002 IEEE Transactions on
Plasma Science v30 4 ISSN 0093-3813 pp 1445-48
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
6
[3] Popov V E Bratsev A N Kuznetsov V A Shtengel S V and Ufimtsev A A 2011 Journal of Physics Conference Series 275 012015 doi1010881742-65962751012015
[4] Heberlin J Murphy A B 2008 J Phys D Appl Phys 41 053001 [5] Jeniˇsta J Takana H Nishiyama H Bartlovacutea M Aubrecht V Kˇrenek P Hrabovskacutey M Kavka
T Sember V and Maˇslacuteani A 2011 J Phys D Appl Phys 44 435204 [6] Messerle V E Ustimenko A B Askarova A S and Nagibin A O 2010 Thermophysics and
Aeromechanics Vol 17 N3 435-444 DOI 101134S0869864310030145 [7] Internet link httpwwwwestinghouse-plasmacomtechnologyplasma-torches (access date
22062012)1-14 [8] Hacala A Michon U 2009 ISPC19 Bochum Germany proceedings 39 P21404 [9] Ni Guo-Hua Meng Yue-Dong Cheng Cheng Lan Yan 2010 CHIN PHYS LETT Vol 27 No 5
055203 [10] Guohua Ni Peng Zhao Cheng Cheng Ye Song Hirotaka Toyoda and Yuedong Meng 2012
Plasma Sources Sci Technol 21 015009 [11] Rutberg Ph 2009 Physics and Technology of High-Current Discharges in Dense Gas Media and
Flows Nova Science Publishers Inc New York ISBN 978-1-60692-232-3 214 p
[12] Rutberg Ph G Kumkova I I Kuznetsov V E Popov S D Rutberg A Ph Safronov A A Shiryaev
V N and Surov A V 2007 IEEE Pulsed Power Conference (PPPS-2007) Digest of Technical
Papers 1976-2007 June 17-20 2007 Albuquerque New Mexico USA IEEE Catalog
Number 07CH37864C ISBN 1-4244-0914-4 Library of Congress 81-644315 Omnipress
Madison p 1556-59
[13] Rutberg Ph G Popov S D Safronov A A Serba E O Nakonechny Gh V 2007 XXVIII
Internatuional Conference on Phenomena in Ionized Gases (ICPIG 2007) Proceedings
Prague Czech Republic ISBN 978-80-87026-01-4 Published by Institute of Plasma Physics
AS CR vvi (4P11-07) p1762-65 [14] Rutberg Ph G Safronov A A Popov S D Surov A V and Nakonechny Gh V 2005 Plasma Phys
Control Fusion 471681-96 [15] Rutberg Ph G Lukyanov S A Kiselev A A Kuschev S A Nakonechny Gh V Nikonov A V
Popov S D Serba E O Spodobin V A and Surov A V 2011 Journal of Physics Conference Series 275 012006 doi1010881742-65962751012006
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
7
enough time to relax at the current zero crossing and the arc is ignited in the same channel in the each
following half-period The solenoid which is forming a longitudinal magnetic field in the hollow
electrode volume is coaxially put on the electrode for the intensification of the arc attachment
rotation The solenoid coil is powered from the AC power supply so that at the arc current polarity
changing the current direction in the coil changes Thus despite of the arc current polarity changing
the force direction acting on the arc attachment and promoting the intensification of its rotational
movement remains the same The magnitude of force acting on the charged particles of the arc column
in the arc attachment area changes due to the sinusoidal change of the current in the coil This force
reaches the maximum value at the peak arc current and decreases at the moment of the current
transition through zero The connection of the AC coil in the opposite direction can cause the braking
or even arc attachment moving towards to the gas flow which is undesirable as it leads to increase of
the electrode material erosion and the reduction of its lifetime
The magnetic field produced by a solenoid in the electrode channel was obtained using computer
simulation Figure 4 shows the schematic diagram of the electrode with the solenoid (a) and
characteristic graphs of distribution of value of magnetic inductance on a working surface of an
electrode in the longitudinal direction (b) and its distributions along the diameter of the electrode
chamber (c) Values of magnetic inductance during the moments of time matching to maxima of
currents in the solenoid windings for the points of space laying on lines L and D are built in the
graphs Line L represents the generating line of the working surface and line D coincides with the
diameter
A
L
D
A
L
D
(a)
00 02 04 06 08 lL
4
8
12
16
20
B10-3
T (b)
00 02 04 06 08 dD
4
8
12
16
20
B10-3T
1
2
3
4
5
(c)
Figure 3 Schematic diagram of the hollow cylindrical electrode with solenoid (a) and characteristic
graphs of distribution of the value of the magnetic inductance in the electrode channel at the moment
of current maximum in the solenoid windings Lines D and L ndash lines along which are calculated the
values of magnetic inductance presented in graphs (b) - longitudinal distribution of the magnetic
inductance along the electrode working surface (c) - distribution of the magnetic inductance on the
diameter of the electrode chamber Point A belongs to ring area with the maximum magnetic field
density on the electrode working surface Curve 1 shows magnetic inductance for plasma torch
working with arc current of 47 A curves 2-5 correspond the plasma torch working modes with arc
current of 85 A
Analysis of materials of a high-speed video shooting of the arc attachment movement along the
electrode surface shows dependences of the arc attachment versus plasma torch operating parameters
and characteristics of applied magnetic field Shooting was carried out through the peep holes located
in a back part of the electrode channel with use of High Speed Video Cameras ldquoCitius Imaging C100
Centuriordquo with a speed 4000 fps and exposure 2 micros Speed of the arc attachment movement round a
circle is non-uniform it increases under the influence of electromagnetic forces at current maximum
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
4
of a coil and decreases with its transition through zero Mean values of tangential speed of the arc
attachment were calculated on 50 complete revolutions for different regimes showed in figure 3 For
the arc current about 47 A without applied magnetic field the attachment velocity is about 25 ms and
it is rising twice when applied magnetic field density achieves 10-2
T For the arc current about 85 A
without applied magnetic field the attachment velocity is about 32 ms and it is rising from 4 to
14 ms when applied magnetic field density accordingly changes from 7x10-3
T to 20x10-3
T Numerical calculations of gas-dynamic parameters in the near electrode area for comparison the arc
attachment rotation speed and the gas flow speed for the examined modes of the plasma forming gas
feeding were carried out Considering the fact that the main flow in the back part of the channel is
formed by the cold gas submitted tangentially and that the part of the arc column situated there
occupies rather small share of the channel volume so that parameters of a cold gas flow rate (without
arc presence) were calculated in a first approximation The task was solved in the stationary statement
for the viscous compressed air The approach developed for high-speed compressible flows was
chosen Besides the Navier-Stokes equations and the continuity equations the system was
supplemented by the energy equation and a set of the empirical constants accompanying the
connection of the turbulence model (k-ε) at calculations The Figure 5 shows the calculation data
(a)
( )c
( )b
( )d
( )f
( )e
Figure 5 Plasma forming gas magnitude speed fields (ms) in the electrode channel of
the plasma torch in dependence of a total flow rate in near electrode loops of the plasma
forming gas (air) (a) - 5 gs (b) - 94 gs (c) - 122 gs in the upstream and the
downstream feeding circuits of the plasma forming gas (air) (d)-(f) - Representation of
velocity fields for different distribution of flow rates between upstream and downstream
gas feeding circuits Arrows show the arc attachment areas (d) - arc attachment is
situated in back end of electrode (e) - in the middle area and (f) - in the downstream end
Total gas flow rate - 45 gs
Figure 5 shows calculated gas velocity fields for plasma torch operation modes with different air flow rates supplied to the near electrode area On each diagram can be seen location of slower near-wall flow bounded on both sides (upstream and downstream) of a faster flow Such areas are marked by arrows in diagrams (d)-(f) The electric arc attachment of working plasma torch stabilized in these locations where the tangential velocity component makes the main contribution to the velocity magnitude (gt99) Diagrams (a)-(c) show velocity fields calculated for plasma torch operation modes with different air flow rates supplied to the near electrode area Flow rates were from 5 to 122 gs Average speeds of the arc attachment moving under the influence of a magnetic field with an
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
5
inductance of about 10-2
T were experimentally obtained for the same flow rate modes The arc current was 47 A The average speed of the arc attachment under these conditions is approximately 3 times less than the gas velocity in the near-wall electrode channel area
Figure 5 (d)-(f) shows gas magnitude velocity fields for three modes of gas feeding with different ratios of its flow rates through upstream and downstream near electrode loops The arc rotates in regions bounded on both sides of a faster flow marked by arrows In these regions the tangential velocity is more than 98 of the velocity magnitude The arrows in the diagrams (d) (e) and (f) comply with the trace of the arc at the beginning middle and end of the working electrode surface (in the longitudinal direction) Thus the position of the arc attachment can be adjusted on the working electrode surface in the longitudinal direction This allows organizing a permanent rotational and reciprocating movement of the arc in the long cylindrical electrode over its entire surface by changing the ratio of flow rates in upstream and downstream near-electrode feeding loops For represented on these diagrams modes were experimentally determined speed of the arc attachment moving under the influence of a magnetic field with an inductance of about 14x10
-3 T The average speed of the arc
attachment with a current about 84A slightly lags behind the velocity of the gas flow in the near electrode area and is about 80-90 of it In reviewing should take into account that the values of the arc attachment speed are obtained experimentally and the calculated values of flow rates are approximate and were obtained for the cold flow (excluding the arc in the working volume of the electrode) and that the real value of the flow velocity in the examined area may be different from calculated
The speed of the arc attachment longitudinal motion depends on the rate of change of the flow rate proportion Based on the results of a number of experiments it was offered for our device to organize continuous reciprocating motion of the arc attachment in the longitudinal direction (scanning) with longitudinal speed about 1 cms it is successfully realized by gas supplying system equipped with industrial automatic pressure controllers Long-term 300-hour experiments showed that longitudinal scanning of the arc attachment with its gas-dynamic and magnetic rotation allow providing the uniform wear of the electrode surface The specific erosion value is about 1-3 microgC It is 3 times less than that of the stationary AC plasma torches with the rail-type electrodes working at the same power level with arc currents about 900 A That enables production of the 1 MW industrial plasma torch with the hollow cylindrical electrode assembly with lifetime above 1000 hours at currents in the arc up to 100-200 A
Conclusion Results of experiment directed towards the increase in the lifetime characteristics of electrode units of the powerful high-voltage electric-arc AC plasma torches are presented The solution to the problem of obtainment the uniform wear of a copper hollow cylindrical electrode achieved by the controlled movement of the arc attachment along the working surface was offered Organization of gas supply in the near electrode area and application of alternating magnetic field ensured movement of arc attachment along the surface with average speed from 2 to 14 ms Arc current was about 47A and 84A Gas flow rate in near electrode area was about 45 gs The findings of influence methods on the electric arc attachment by electromagnetic and gas-dynamic forces are presented The erosion of a hollow cylindrical electrode reached only 3 microgC that enables production of the electrode assembly with life time above 1000 hours at currents in the arc up to 100-200 A
Acnowledgements
The work is supported by Russian academy of sciences and also RFBR grants 11-08-01022-a and 12-
08-00916-a Authors also express gratitude to Anton Surov for the provided data of gas-dynamic
calculations References [1] Rutberg Ph G 2003 Plasma Phys Control Fusion 45 957-69 [2] Rutberg Ph G Bratsev A N Safronov A A Surov A V Shegolev V V 2002 IEEE Transactions on
Plasma Science v30 4 ISSN 0093-3813 pp 1445-48
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
6
[3] Popov V E Bratsev A N Kuznetsov V A Shtengel S V and Ufimtsev A A 2011 Journal of Physics Conference Series 275 012015 doi1010881742-65962751012015
[4] Heberlin J Murphy A B 2008 J Phys D Appl Phys 41 053001 [5] Jeniˇsta J Takana H Nishiyama H Bartlovacutea M Aubrecht V Kˇrenek P Hrabovskacutey M Kavka
T Sember V and Maˇslacuteani A 2011 J Phys D Appl Phys 44 435204 [6] Messerle V E Ustimenko A B Askarova A S and Nagibin A O 2010 Thermophysics and
Aeromechanics Vol 17 N3 435-444 DOI 101134S0869864310030145 [7] Internet link httpwwwwestinghouse-plasmacomtechnologyplasma-torches (access date
22062012)1-14 [8] Hacala A Michon U 2009 ISPC19 Bochum Germany proceedings 39 P21404 [9] Ni Guo-Hua Meng Yue-Dong Cheng Cheng Lan Yan 2010 CHIN PHYS LETT Vol 27 No 5
055203 [10] Guohua Ni Peng Zhao Cheng Cheng Ye Song Hirotaka Toyoda and Yuedong Meng 2012
Plasma Sources Sci Technol 21 015009 [11] Rutberg Ph 2009 Physics and Technology of High-Current Discharges in Dense Gas Media and
Flows Nova Science Publishers Inc New York ISBN 978-1-60692-232-3 214 p
[12] Rutberg Ph G Kumkova I I Kuznetsov V E Popov S D Rutberg A Ph Safronov A A Shiryaev
V N and Surov A V 2007 IEEE Pulsed Power Conference (PPPS-2007) Digest of Technical
Papers 1976-2007 June 17-20 2007 Albuquerque New Mexico USA IEEE Catalog
Number 07CH37864C ISBN 1-4244-0914-4 Library of Congress 81-644315 Omnipress
Madison p 1556-59
[13] Rutberg Ph G Popov S D Safronov A A Serba E O Nakonechny Gh V 2007 XXVIII
Internatuional Conference on Phenomena in Ionized Gases (ICPIG 2007) Proceedings
Prague Czech Republic ISBN 978-80-87026-01-4 Published by Institute of Plasma Physics
AS CR vvi (4P11-07) p1762-65 [14] Rutberg Ph G Safronov A A Popov S D Surov A V and Nakonechny Gh V 2005 Plasma Phys
Control Fusion 471681-96 [15] Rutberg Ph G Lukyanov S A Kiselev A A Kuschev S A Nakonechny Gh V Nikonov A V
Popov S D Serba E O Spodobin V A and Surov A V 2011 Journal of Physics Conference Series 275 012006 doi1010881742-65962751012006
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
7
of a coil and decreases with its transition through zero Mean values of tangential speed of the arc
attachment were calculated on 50 complete revolutions for different regimes showed in figure 3 For
the arc current about 47 A without applied magnetic field the attachment velocity is about 25 ms and
it is rising twice when applied magnetic field density achieves 10-2
T For the arc current about 85 A
without applied magnetic field the attachment velocity is about 32 ms and it is rising from 4 to
14 ms when applied magnetic field density accordingly changes from 7x10-3
T to 20x10-3
T Numerical calculations of gas-dynamic parameters in the near electrode area for comparison the arc
attachment rotation speed and the gas flow speed for the examined modes of the plasma forming gas
feeding were carried out Considering the fact that the main flow in the back part of the channel is
formed by the cold gas submitted tangentially and that the part of the arc column situated there
occupies rather small share of the channel volume so that parameters of a cold gas flow rate (without
arc presence) were calculated in a first approximation The task was solved in the stationary statement
for the viscous compressed air The approach developed for high-speed compressible flows was
chosen Besides the Navier-Stokes equations and the continuity equations the system was
supplemented by the energy equation and a set of the empirical constants accompanying the
connection of the turbulence model (k-ε) at calculations The Figure 5 shows the calculation data
(a)
( )c
( )b
( )d
( )f
( )e
Figure 5 Plasma forming gas magnitude speed fields (ms) in the electrode channel of
the plasma torch in dependence of a total flow rate in near electrode loops of the plasma
forming gas (air) (a) - 5 gs (b) - 94 gs (c) - 122 gs in the upstream and the
downstream feeding circuits of the plasma forming gas (air) (d)-(f) - Representation of
velocity fields for different distribution of flow rates between upstream and downstream
gas feeding circuits Arrows show the arc attachment areas (d) - arc attachment is
situated in back end of electrode (e) - in the middle area and (f) - in the downstream end
Total gas flow rate - 45 gs
Figure 5 shows calculated gas velocity fields for plasma torch operation modes with different air flow rates supplied to the near electrode area On each diagram can be seen location of slower near-wall flow bounded on both sides (upstream and downstream) of a faster flow Such areas are marked by arrows in diagrams (d)-(f) The electric arc attachment of working plasma torch stabilized in these locations where the tangential velocity component makes the main contribution to the velocity magnitude (gt99) Diagrams (a)-(c) show velocity fields calculated for plasma torch operation modes with different air flow rates supplied to the near electrode area Flow rates were from 5 to 122 gs Average speeds of the arc attachment moving under the influence of a magnetic field with an
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
5
inductance of about 10-2
T were experimentally obtained for the same flow rate modes The arc current was 47 A The average speed of the arc attachment under these conditions is approximately 3 times less than the gas velocity in the near-wall electrode channel area
Figure 5 (d)-(f) shows gas magnitude velocity fields for three modes of gas feeding with different ratios of its flow rates through upstream and downstream near electrode loops The arc rotates in regions bounded on both sides of a faster flow marked by arrows In these regions the tangential velocity is more than 98 of the velocity magnitude The arrows in the diagrams (d) (e) and (f) comply with the trace of the arc at the beginning middle and end of the working electrode surface (in the longitudinal direction) Thus the position of the arc attachment can be adjusted on the working electrode surface in the longitudinal direction This allows organizing a permanent rotational and reciprocating movement of the arc in the long cylindrical electrode over its entire surface by changing the ratio of flow rates in upstream and downstream near-electrode feeding loops For represented on these diagrams modes were experimentally determined speed of the arc attachment moving under the influence of a magnetic field with an inductance of about 14x10
-3 T The average speed of the arc
attachment with a current about 84A slightly lags behind the velocity of the gas flow in the near electrode area and is about 80-90 of it In reviewing should take into account that the values of the arc attachment speed are obtained experimentally and the calculated values of flow rates are approximate and were obtained for the cold flow (excluding the arc in the working volume of the electrode) and that the real value of the flow velocity in the examined area may be different from calculated
The speed of the arc attachment longitudinal motion depends on the rate of change of the flow rate proportion Based on the results of a number of experiments it was offered for our device to organize continuous reciprocating motion of the arc attachment in the longitudinal direction (scanning) with longitudinal speed about 1 cms it is successfully realized by gas supplying system equipped with industrial automatic pressure controllers Long-term 300-hour experiments showed that longitudinal scanning of the arc attachment with its gas-dynamic and magnetic rotation allow providing the uniform wear of the electrode surface The specific erosion value is about 1-3 microgC It is 3 times less than that of the stationary AC plasma torches with the rail-type electrodes working at the same power level with arc currents about 900 A That enables production of the 1 MW industrial plasma torch with the hollow cylindrical electrode assembly with lifetime above 1000 hours at currents in the arc up to 100-200 A
Conclusion Results of experiment directed towards the increase in the lifetime characteristics of electrode units of the powerful high-voltage electric-arc AC plasma torches are presented The solution to the problem of obtainment the uniform wear of a copper hollow cylindrical electrode achieved by the controlled movement of the arc attachment along the working surface was offered Organization of gas supply in the near electrode area and application of alternating magnetic field ensured movement of arc attachment along the surface with average speed from 2 to 14 ms Arc current was about 47A and 84A Gas flow rate in near electrode area was about 45 gs The findings of influence methods on the electric arc attachment by electromagnetic and gas-dynamic forces are presented The erosion of a hollow cylindrical electrode reached only 3 microgC that enables production of the electrode assembly with life time above 1000 hours at currents in the arc up to 100-200 A
Acnowledgements
The work is supported by Russian academy of sciences and also RFBR grants 11-08-01022-a and 12-
08-00916-a Authors also express gratitude to Anton Surov for the provided data of gas-dynamic
calculations References [1] Rutberg Ph G 2003 Plasma Phys Control Fusion 45 957-69 [2] Rutberg Ph G Bratsev A N Safronov A A Surov A V Shegolev V V 2002 IEEE Transactions on
Plasma Science v30 4 ISSN 0093-3813 pp 1445-48
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
6
[3] Popov V E Bratsev A N Kuznetsov V A Shtengel S V and Ufimtsev A A 2011 Journal of Physics Conference Series 275 012015 doi1010881742-65962751012015
[4] Heberlin J Murphy A B 2008 J Phys D Appl Phys 41 053001 [5] Jeniˇsta J Takana H Nishiyama H Bartlovacutea M Aubrecht V Kˇrenek P Hrabovskacutey M Kavka
T Sember V and Maˇslacuteani A 2011 J Phys D Appl Phys 44 435204 [6] Messerle V E Ustimenko A B Askarova A S and Nagibin A O 2010 Thermophysics and
Aeromechanics Vol 17 N3 435-444 DOI 101134S0869864310030145 [7] Internet link httpwwwwestinghouse-plasmacomtechnologyplasma-torches (access date
22062012)1-14 [8] Hacala A Michon U 2009 ISPC19 Bochum Germany proceedings 39 P21404 [9] Ni Guo-Hua Meng Yue-Dong Cheng Cheng Lan Yan 2010 CHIN PHYS LETT Vol 27 No 5
055203 [10] Guohua Ni Peng Zhao Cheng Cheng Ye Song Hirotaka Toyoda and Yuedong Meng 2012
Plasma Sources Sci Technol 21 015009 [11] Rutberg Ph 2009 Physics and Technology of High-Current Discharges in Dense Gas Media and
Flows Nova Science Publishers Inc New York ISBN 978-1-60692-232-3 214 p
[12] Rutberg Ph G Kumkova I I Kuznetsov V E Popov S D Rutberg A Ph Safronov A A Shiryaev
V N and Surov A V 2007 IEEE Pulsed Power Conference (PPPS-2007) Digest of Technical
Papers 1976-2007 June 17-20 2007 Albuquerque New Mexico USA IEEE Catalog
Number 07CH37864C ISBN 1-4244-0914-4 Library of Congress 81-644315 Omnipress
Madison p 1556-59
[13] Rutberg Ph G Popov S D Safronov A A Serba E O Nakonechny Gh V 2007 XXVIII
Internatuional Conference on Phenomena in Ionized Gases (ICPIG 2007) Proceedings
Prague Czech Republic ISBN 978-80-87026-01-4 Published by Institute of Plasma Physics
AS CR vvi (4P11-07) p1762-65 [14] Rutberg Ph G Safronov A A Popov S D Surov A V and Nakonechny Gh V 2005 Plasma Phys
Control Fusion 471681-96 [15] Rutberg Ph G Lukyanov S A Kiselev A A Kuschev S A Nakonechny Gh V Nikonov A V
Popov S D Serba E O Spodobin V A and Surov A V 2011 Journal of Physics Conference Series 275 012006 doi1010881742-65962751012006
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
7
inductance of about 10-2
T were experimentally obtained for the same flow rate modes The arc current was 47 A The average speed of the arc attachment under these conditions is approximately 3 times less than the gas velocity in the near-wall electrode channel area
Figure 5 (d)-(f) shows gas magnitude velocity fields for three modes of gas feeding with different ratios of its flow rates through upstream and downstream near electrode loops The arc rotates in regions bounded on both sides of a faster flow marked by arrows In these regions the tangential velocity is more than 98 of the velocity magnitude The arrows in the diagrams (d) (e) and (f) comply with the trace of the arc at the beginning middle and end of the working electrode surface (in the longitudinal direction) Thus the position of the arc attachment can be adjusted on the working electrode surface in the longitudinal direction This allows organizing a permanent rotational and reciprocating movement of the arc in the long cylindrical electrode over its entire surface by changing the ratio of flow rates in upstream and downstream near-electrode feeding loops For represented on these diagrams modes were experimentally determined speed of the arc attachment moving under the influence of a magnetic field with an inductance of about 14x10
-3 T The average speed of the arc
attachment with a current about 84A slightly lags behind the velocity of the gas flow in the near electrode area and is about 80-90 of it In reviewing should take into account that the values of the arc attachment speed are obtained experimentally and the calculated values of flow rates are approximate and were obtained for the cold flow (excluding the arc in the working volume of the electrode) and that the real value of the flow velocity in the examined area may be different from calculated
The speed of the arc attachment longitudinal motion depends on the rate of change of the flow rate proportion Based on the results of a number of experiments it was offered for our device to organize continuous reciprocating motion of the arc attachment in the longitudinal direction (scanning) with longitudinal speed about 1 cms it is successfully realized by gas supplying system equipped with industrial automatic pressure controllers Long-term 300-hour experiments showed that longitudinal scanning of the arc attachment with its gas-dynamic and magnetic rotation allow providing the uniform wear of the electrode surface The specific erosion value is about 1-3 microgC It is 3 times less than that of the stationary AC plasma torches with the rail-type electrodes working at the same power level with arc currents about 900 A That enables production of the 1 MW industrial plasma torch with the hollow cylindrical electrode assembly with lifetime above 1000 hours at currents in the arc up to 100-200 A
Conclusion Results of experiment directed towards the increase in the lifetime characteristics of electrode units of the powerful high-voltage electric-arc AC plasma torches are presented The solution to the problem of obtainment the uniform wear of a copper hollow cylindrical electrode achieved by the controlled movement of the arc attachment along the working surface was offered Organization of gas supply in the near electrode area and application of alternating magnetic field ensured movement of arc attachment along the surface with average speed from 2 to 14 ms Arc current was about 47A and 84A Gas flow rate in near electrode area was about 45 gs The findings of influence methods on the electric arc attachment by electromagnetic and gas-dynamic forces are presented The erosion of a hollow cylindrical electrode reached only 3 microgC that enables production of the electrode assembly with life time above 1000 hours at currents in the arc up to 100-200 A
Acnowledgements
The work is supported by Russian academy of sciences and also RFBR grants 11-08-01022-a and 12-
08-00916-a Authors also express gratitude to Anton Surov for the provided data of gas-dynamic
calculations References [1] Rutberg Ph G 2003 Plasma Phys Control Fusion 45 957-69 [2] Rutberg Ph G Bratsev A N Safronov A A Surov A V Shegolev V V 2002 IEEE Transactions on
Plasma Science v30 4 ISSN 0093-3813 pp 1445-48
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
6
[3] Popov V E Bratsev A N Kuznetsov V A Shtengel S V and Ufimtsev A A 2011 Journal of Physics Conference Series 275 012015 doi1010881742-65962751012015
[4] Heberlin J Murphy A B 2008 J Phys D Appl Phys 41 053001 [5] Jeniˇsta J Takana H Nishiyama H Bartlovacutea M Aubrecht V Kˇrenek P Hrabovskacutey M Kavka
T Sember V and Maˇslacuteani A 2011 J Phys D Appl Phys 44 435204 [6] Messerle V E Ustimenko A B Askarova A S and Nagibin A O 2010 Thermophysics and
Aeromechanics Vol 17 N3 435-444 DOI 101134S0869864310030145 [7] Internet link httpwwwwestinghouse-plasmacomtechnologyplasma-torches (access date
22062012)1-14 [8] Hacala A Michon U 2009 ISPC19 Bochum Germany proceedings 39 P21404 [9] Ni Guo-Hua Meng Yue-Dong Cheng Cheng Lan Yan 2010 CHIN PHYS LETT Vol 27 No 5
055203 [10] Guohua Ni Peng Zhao Cheng Cheng Ye Song Hirotaka Toyoda and Yuedong Meng 2012
Plasma Sources Sci Technol 21 015009 [11] Rutberg Ph 2009 Physics and Technology of High-Current Discharges in Dense Gas Media and
Flows Nova Science Publishers Inc New York ISBN 978-1-60692-232-3 214 p
[12] Rutberg Ph G Kumkova I I Kuznetsov V E Popov S D Rutberg A Ph Safronov A A Shiryaev
V N and Surov A V 2007 IEEE Pulsed Power Conference (PPPS-2007) Digest of Technical
Papers 1976-2007 June 17-20 2007 Albuquerque New Mexico USA IEEE Catalog
Number 07CH37864C ISBN 1-4244-0914-4 Library of Congress 81-644315 Omnipress
Madison p 1556-59
[13] Rutberg Ph G Popov S D Safronov A A Serba E O Nakonechny Gh V 2007 XXVIII
Internatuional Conference on Phenomena in Ionized Gases (ICPIG 2007) Proceedings
Prague Czech Republic ISBN 978-80-87026-01-4 Published by Institute of Plasma Physics
AS CR vvi (4P11-07) p1762-65 [14] Rutberg Ph G Safronov A A Popov S D Surov A V and Nakonechny Gh V 2005 Plasma Phys
Control Fusion 471681-96 [15] Rutberg Ph G Lukyanov S A Kiselev A A Kuschev S A Nakonechny Gh V Nikonov A V
Popov S D Serba E O Spodobin V A and Surov A V 2011 Journal of Physics Conference Series 275 012006 doi1010881742-65962751012006
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
7
[3] Popov V E Bratsev A N Kuznetsov V A Shtengel S V and Ufimtsev A A 2011 Journal of Physics Conference Series 275 012015 doi1010881742-65962751012015
[4] Heberlin J Murphy A B 2008 J Phys D Appl Phys 41 053001 [5] Jeniˇsta J Takana H Nishiyama H Bartlovacutea M Aubrecht V Kˇrenek P Hrabovskacutey M Kavka
T Sember V and Maˇslacuteani A 2011 J Phys D Appl Phys 44 435204 [6] Messerle V E Ustimenko A B Askarova A S and Nagibin A O 2010 Thermophysics and
Aeromechanics Vol 17 N3 435-444 DOI 101134S0869864310030145 [7] Internet link httpwwwwestinghouse-plasmacomtechnologyplasma-torches (access date
22062012)1-14 [8] Hacala A Michon U 2009 ISPC19 Bochum Germany proceedings 39 P21404 [9] Ni Guo-Hua Meng Yue-Dong Cheng Cheng Lan Yan 2010 CHIN PHYS LETT Vol 27 No 5
055203 [10] Guohua Ni Peng Zhao Cheng Cheng Ye Song Hirotaka Toyoda and Yuedong Meng 2012
Plasma Sources Sci Technol 21 015009 [11] Rutberg Ph 2009 Physics and Technology of High-Current Discharges in Dense Gas Media and
Flows Nova Science Publishers Inc New York ISBN 978-1-60692-232-3 214 p
[12] Rutberg Ph G Kumkova I I Kuznetsov V E Popov S D Rutberg A Ph Safronov A A Shiryaev
V N and Surov A V 2007 IEEE Pulsed Power Conference (PPPS-2007) Digest of Technical
Papers 1976-2007 June 17-20 2007 Albuquerque New Mexico USA IEEE Catalog
Number 07CH37864C ISBN 1-4244-0914-4 Library of Congress 81-644315 Omnipress
Madison p 1556-59
[13] Rutberg Ph G Popov S D Safronov A A Serba E O Nakonechny Gh V 2007 XXVIII
Internatuional Conference on Phenomena in Ionized Gases (ICPIG 2007) Proceedings
Prague Czech Republic ISBN 978-80-87026-01-4 Published by Institute of Plasma Physics
AS CR vvi (4P11-07) p1762-65 [14] Rutberg Ph G Safronov A A Popov S D Surov A V and Nakonechny Gh V 2005 Plasma Phys
Control Fusion 471681-96 [15] Rutberg Ph G Lukyanov S A Kiselev A A Kuschev S A Nakonechny Gh V Nikonov A V
Popov S D Serba E O Spodobin V A and Surov A V 2011 Journal of Physics Conference Series 275 012006 doi1010881742-65962751012006
12th High-Tech Plasma Processes Conference (HTPP-12) IOP PublishingJournal of Physics Conference Series 406 (2012) 012007 doi1010881742-65964061012007
7